CA1158739A

CA1158739A - Distributed network synchronization system

Info

Publication number: CA1158739A
Application number: CA000350913A
Authority: CA
Inventors: William Rodman; Peter Boland
Original assignee: Manitoba Telephone System
Current assignee: Manitoba Telephone System
Priority date: 1980-04-30
Filing date: 1980-04-30
Publication date: 1983-12-13
Also published as: EP0131662A1

Abstract

"DISTRIBUTED NETWORK SYNCHRONIZATION SYSTEM"
ABSTRACT OF THE DISCLOSURE
A synchronization system is provided for a tree-type transmission system comprising a central station connected to a plurality of remote stations in an effectively sequen-tial manner, each station including transmitting and receiv-ing means for digital data in a sequence of frames. Each remote station is instructed regularly by the central station of the time delay between the remote station and the central station. The remote station stores the time delay and arranges to advance information transmitted by the remote station so as to be received by the central station within the proper position in the frame. The time delay is measured by the central station by sensing a pattern of bits repeti-tively transmitted by the remote station and comparing the received pattern with a stored pattern and counting the num-ber of shifts of the received pattern necessary to match the stored pattern. The delay stored by the remote station is tuned to one quarter of a bit to ensure accurate synchron-ization.

Description

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02 This invention relates to two-way digital ~3 transmission systems, and it is particularly directed to a 04 synchronization system therefor.
05 ~ number of diEferent of types of systems have been 06 proposed for distributing information to subscribers either on 07 an on-call basis or otherwise, and for receiving information 08 from various subscriber stations. InEormation signals to be 09 received are, for example, wa~er and hydro meter readings, burglar and fire alarm signals, subscriber initiated reques-ts 11 for service, telephone signalling and communication signals, 12 etc. Signals to be distributed sometimes include video textual 13 information, remote load management si~nals, remote control 1~ signals, telephony signalling and communication signals, facsimile si~nals, etc.
16 Arrangements in various forms have been proposed for 17 providing the distribution and collection of such signals.
18 However a system to accommodate all of the above services, and 19 which facilitates the addition of services as demand increases has been found to be difficult to provide. One of the reasons 21 for this difficulty is the problem of providing synchronization 22 between the types of signals being transmitted to subscriber 23 stations and being received from subscriber stations at various 24 distances from a central distribution office. While each subscriber station could be addressed in turn, e.g.
26 asynchronously, the time delays for transmission and reception 27 of information would dictate an inefficient loading of the 28 maximum possible capacity of the system.
29 Furthermore, where temperatures vary significantly between day and night, and with the seasons, transmission time 31 delays would be variable, further compounding the 32 synchronization problem, particularly where time variations are 33 not the same as between various subscribers.
34 While each individual subscriber station could be adjusted manually to compensate for its own time delay, the 36 aforenoted variations with temperature would be make subscriber 37 station servicing both frequent and expensive. Further, as the 38 system becomes loaded with more and more subscriber s~ation, a 39 serviceman would have to be dispatched to each subscriber '~

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~1 2 02 station as it is brought into the system to manually 03 synchronize it with the others.
04 The present invention relates to an automatic 05 synchronization system for use in a distributed transmission 06 network. It is particularly useful in a "tree" type network, 07 such as is commonly used for distribution of CATV, (although 08 other types of networks can be used) where a single coaxial 09 cable, fiber optic link or the like~ feeds a plurality of subscribers, therebeing a plurality of branches connected to a 11 main trunk, with subscriber nodes connected to each branch and, 12 a plurality of subscriber stations connected to each node.
13 Efficient loading of the system is obtained by the use of a 14 standard and well known DS-l digital data format, although lS other forms of digital data transmission can use the present 16 invention.
17 In a typical DS-l format, the data siynal is 18 forwarded in frames, 800 frames per second being transmitted.
19 Each frame is comprised of 193 bits, divided into 24 time slots, and one frame bit, each time slot being comprised of 8 21 bits. Each of the 24 time slots thus provides one channel.
22 The 193rd bit in each frame is called a frame bit.
23 Twelve frames form a superframe; the frame bits of each 12 24 frames forming a predetermined repeating pattern. The frame bit pattern is used for synchronization.
26 The 8th bit of each time slot on the 6th frame and 27 each 6th frame thereafter forms a low speed so-called "A"
28 signalling channel. The 8th bit of each time slot on the 12th 29 frame and each 12th frame thereafter forms a second low speed so-called "B" signalling channel. Each of the A and B
31 signalling channels provides 24, 666 bit per second data 32 channels. Each of the 24 time slots within a frame provides a 33 64 kilobits per second data channel.
34 A problem exists in utilizing the DS-l format in a distributed type "tree" system, in that where the central 36 station addresses a particular remote station and instructs it 37 to transmit within a designated time slot, -the remote station 38 clock must not only be synchroni~ed to the cen-tral station 39 clock, but also must transmit in a manner such that the signal 3 ~Sb~739 will be received at the central station at the proper time.
Should the central station also address another remote sta-tion, much closer to the central station, to transmit in the next time slot ~ollowing the Eirst, delay in the transmis-sion Line carrying the signal from the farther remote station could cause the signal for the first time slot to be delayed sufficiently such that it overlaps the signal in the second time slot upon arrival at the central station. As noted earlier, this could be connected by manually adjusting each remote station continuously.
In accordance with the present invention there is provided a digital transmission system comprising a central station and a plurality of remote stations, each station in-cluding means for transmitting and receiving digital data in a sequence of frames, transmission means arranged between said central station and each of said remote stations and ~ causing a variable inherent delay therebetween dependent upon ; the location of the respective remote station, the centralstation including means for transmitting a first signal to each of said remote stations chosen in turn and for receiv-ing a signal therefrom dependent on the first signal and means for producing from said first signal and said received signal a delay signal representative of the inherent delay relative to the chosen remote station and for transmitting said delay signal to said remote station, and each remote station including means for receiving and storing said delay , .

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signal and means Eor changing the time of transmission of the transmission means of said remote station in dependence upon said stored delay.
Another aspect of the invention provides a digital transmission system comprising a central s~atl~n and a plur-ality of remote stations, each station including means for transmitting and receiving digital data signal in a sequence of frames, transmission means arranged between said central station and each oE said remote stations and causing a var-iable inherent delay therebetween dependent upon the loca-tion of the respective remote station, the central station including means Eor transmitting a Eirst signal to a chosen one of said remote stations and for receiving a signal there-from dependent on the first signal and means for producing from said first signal and said received signal a delay signal representative of the inherent delay relative to the chosen remote station and for transmitting said delay signal to said remote station, and each remote station including means for receiving and storing said delay signal, means for synchronizing a nominal time of transmission of the transmission means of said remote station with data signals received from said central station and means for advancing the actual time of transmission of the transmission means relative to said nominal time in dependence upon said stored delay.
A yet further aspect of the invention provides a ~~ .

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a digital transmission system comprising a central station and a plurality of remote stations, each station including means Eor transmitting and receiving digital data in a se-quence of frames, tree-type transmission means arranged from said central station to each of said remote stations effec-tively sequentially and causing a variable inherent delay be-tween the central station and each of the remote stations de-pendent upon the location of the respective remote station on the transmission means, the central station including means for transmitting a first signal to each of said remote stations chosen in turn and for receiving a signal therefrom dependent on the first signal and means for producing from said first signal and said received signal a delay signal representative of the inherent delay relative to the chosen remote station and for transmitting said delay signal to said - remote station, and each remote station including means for receiving and storing said delay signal, means for synchroni-zing a nominal time of transmission of the transmission means of said remote station with data signals received from said central station and means for advancing the actual time of transmission of the transmission means relative to sai.d nom-inal time in dependence upon said stored delay.
A better understanding o the invention will be obtained by reference to the detailed description of the pre-ferred emboàiment below, with reference to the following draw-ings, in which:

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Figure lA is a block diagram of a tree-type digital transmission system;
Figure 2 is a time graph showing the transmlssion times of a pair of remote stations within adjacent time slots;
Figure 3 is a block diagram used to illustrate the general idea oE the invention;
Fi.gure 4 is a block diagram o.E a time compensation system at a remote station;
Figure 5 is a logic diagram of a time compensation system at a remote station;
Figure 6 is a logic diagram of a fine time compen-sation measurement circuit according to the preferred embodi-ment of the invention; and Figure 7 is a logic diagram oE the compensation : measurement system at the central control.
Fi.gure 8 is a block diagram of a system using the present invention, : Figure ~ is a diagram of a preferred receive syn-chronization circuit for use in the system of Figure 8, and Figures 10 and lL are diagrams of two forms of de-lay build-out circuits for use in the system of Figure 8.
Turning now to Figure 1, a central station 11 is connected to a pl.urality of remote stations 12 by means of a main trunk 13, having branch feeders 1~. The branch feeders can be connected to the main trunk via intermediate terminals 15. Intermediate terminals 15 need not be used ,.

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if the network otherwise does not require them, and main trunk 13 can be connected directly to branch feeders or may form a Eeeder itself. Groups o:E subscriber terminals 16 are connected to remote stations 12. In practice, there may be up to, for example, 12 subscriber terminals connected to each remote ~5~73~

02 station 12. A remote statio~, in practice, is usually located 03 in a neighbourhood area and consequently the subscriber drops 04 interconnecting subscriber terminals 16 with the corresponding 05 remote stations are short with no practical transmission delay.
06 The system is laid out similar to a cable TV system, but 2-way 07 digital transmission is utilized.
08 The trunk and branch feeders typically are coaxial 09 cable, but may be some other medium of transmission, such as optical fibers. A successful digital transmission protocol in 11 which the present invention used is the DS-l type system, 12 described earlier. Preferably there are two DS-1 channels in 13 each direction, one channel in each direction carrying the 14 inverse signal o~ the other, to facilitate detection of errors.
Communication between the central control and the remote 16 stations is effected in such a system by the central station 17 addressing individual remote stations in packets of data, and 18 instructing them to transmit data stored therein back to the 19 central station in designated time slots. The remote stations, in response, transmit packets of data in the designated time 21 slots.
22 To illustrate the invention, consider now Figures 1 23 and 2 together. Let us assume that the central station 24 instructs the remote station RSl to transmit within a first time slot TSl, and remote station RS2 to transmit in a second, 26 immediately following time slot TS2. ~he central station is 27 continuously sending data on the trunk and branch feeders, 28 including frame bits. These are used by the remote stations 29 RSl and RS2 to synchronize their internal clocks, in a well known manner.
31 However due the transmission delay within the main 32 and branch feeders, the synchroni2ing pulses arrive at remote 33 station RS2 first and later at remote ~tation RSl. Accordingly 3~ their internal clocks are not in precise time with each other, nor with central station 11.
36 In the LDEAL condition, in which there is no time 37 delay, a return signal from station RSl would appear precisely 38 within the time boundaries of time slot TSl, and the signal 39 from remote station RS2 would appear precisely within -the ~s~

~2 boundaries of time slot TS2, both time slots occurring at 03 precisely the same instant at remote stations RSl and RS2 and 04 also at central station 11.
05 However due to the lack of synchronization between 06 the timing of the internal clocks of remote stations RSl and 07 RS2 and central station 11, caused by the transmission time 08 delay in the main and branch feeders, and due to the time delay 09 itself, the return signal from remote station RSl arrives at central station 11 considerably delayed in time, 11 (UNCOMPENSATED). Since remote station RS2 is closer to central 12 station 11, but still is some distance therefrom, its signal 13 arrives at central station 11 at time slot TS2 delayed from its 14 ideal time, but not delayed as severely as the signal from remote station RSl. It may be seen that at central station 11 16 the signals overlap, and this causes errors in decoding.
17 In the present invention, however, automatic means is 18 provided for delaying the time of transmission of the signal 19 Erom remote station RSl by an amount which causes it to arrive at the central station in the next frame at a ti~e which 21 exactly compensates for the delay in the main and branch 22 feeders, and as well for automatically causing the delay of the 23 signal from remote station RS2 an amount sufficient to cause it 24 to arrive at central station 11 exactly in time of time slot

2~ TS2 in the next frame a~ the central station. The 26 compensated two signals (COMPENSATÆD) are showr~ in Figure 2 27 arriving at the central station with ideal timing, as a result 28 of the aforenoted advancement.
29 The present invention thus provides automatic timing compensation which is adjustable in a dynamic manner to correct 31 for variation in delay caused by temperature changes, aging o~
32 components, etc. There is no need for periodic manual 33 adjustment at the remote stations.
34 The basic idea of the invention will now be described in simple terms with -the aid of Figure 3. A central station 31 36 contains a counter 32 and an addressing unit 33. Central 37 station 31 is connected to a remote station 3~ (as well as to 38 other remote stations, not shown) via a two-way DS-l link 35.
39 Normally, the central station 31 provides a 02 continuous two-way DS-l format data stream on DS-l link 35, and 03 all remote stations attempt to synchronize using the frame bits 04 and frame bit pattern noted earlier. ~owever until each remote 05 station is synchronized according to this invention, their 06 transmissions within designated time slots would overlap at the 07 central station 31 for the reasons described earlier.
08 In order to effect synchronization, addressing unit 09 33 addresses remote unit 34, and instructs it to transmit in a given time slot. Remote station 34 retransmits the DS-l signal 11 so that the signal transmitted from the central station 31 is 12 returned. An alternative embodiment can loop the signal back 13 to the central station.
14 At the start of the designated time slot, addressing unit 33 enables counter 32 and transmits a data word in the 16 time slot. This is returned to central station 31 via the loop 17 within remote station 34, and the word is recognized in word 18 detection circuit 36. Upon detection of the word, the counter 19 32 is stopped. The remote station could also be instructed merely to transmit a bit at a given time within the time slot, 21 and the timing eEfected between the beginning of the time slot 22 at the central station and the reception of the bit.
23 Preferably counter 32 counts at a rate Eour times the 24 system clock frequency. Since the delay encountered by the transmitted word in one direction (e.g. from the remote station 26 back to the central station) is the total delay count divided 27 by two, and since the count number is four times the number of 28 clock cycles of the delay to the remote station and return, the 29 number counted divided by 2 is the number of clock counts the return direction signal pulses must be advanced at the remote 31 station in order to be received at the central station in 32 synchronization with the designated time slot. In practice, 33 the delay from the remote station will be one complete frame 34 less the number of counts counted by counter 32 divided by 2.
This can be translated into a delay of one frame less a given 36 number of bits.
37 A signal is then transmitted via the DS-l link 35 to 38 the remote station instructing it to advance its transmission 39 time by the above-determined amount. This number is stored in ~15~7~9 ~2 the remote station and its internal clock is advanced by this 03 amount. The loop should of course be broken once synchronism 0~ has been achieved.
05 Coun~er 32 i9 then reset and the central station 06 addresses another remote station, performing the described 07 functions again. Similarly all the remote stations are 08 addressed and their internal clocks set to the a~ount required 09 to transmit signals to the central station such that they arrive precisely within a proper time slot. The entire system 11 is thereby properly synchronized. Clearly this can be e~fected 12 during any idle periods of the system, and as additional remote 13 stations are added.
14 In the preferred system, a synchroni~ation pattern is received, the pattern being incorporated in the 193rd frame bit 16 of the ~S-l data stream. Using this frame bit pattern, the 17 remote station achieves bit synchronization, and then frame 18 synchronization. The remote station then transmits bac~ to the 19 central station, or an upstream station with which it is communicating, with a delay compensation which is determined as 21 described above, or with alternative methods as will be 22 described below. The build out delay compensation is then 23 adjusted to within 1/4 bit, whereupon the signal is received at 24 the central station or at the upstream destination exactly in synchronization with a predetermined frame.
26 Figure 4 is a block diagram showing in more detail 27 one embodiment of the synchronization system within remote 28 station 34. The bidirectional DS-l stream 41 received from the 29 trunk and/or branch feeders are coupled through filter 42 to modem 43. Here the DS-l stream is demodulated and is applied 31 via an internal bus 44 to translation circuitry 45.
32 Translation circuitry 45 decodes the incoming bit stream and 33 assuming the bits are in local synchronization applies the bit 34 stream via modems 46 and combiners 47 to individual subscriber drops 48 which are connected to subscriber terminals 16 (Figure 36 1).
37 Signals from subscriber terminals 16 are connected 38 via subscriber drops 48 and combiners 47 into modems 46 which 39 apply the combined signal to data control circuitry 49.

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02 The operation of translation circuitry 45, combiners 03 47 and data control circuitry 49 is not pertinent to the 04 present invention. Su~fice to say that incoming data signals 05 designated ~or specific subscriber terminals are received on 06 the incoming DS-l stream and are properly applied thereto.
07 Similarly signals from individual subscriber terminals 16 are 08 applied to combiners 47 via subscriber drops 48, are applied to 09 data control circuitry 49 via modems 46t for transmission on the downstream DS-l stream. The packetization and control is 11 effected by a microprocessor 410 with associated circuitry, 12 connected to translation circuitry 45 and data control 13 circuitry 49.
14 The output signal from data control circuitry 49 is applied to a delay compensation circuit 411, which is connected 16 to microprocessor 410. The output signal from delay 17 compensation circuit 411 is connected to the input of modem 43, 18 the output of which is connected through filter 42 to the 19 outgoing DS-l stream 41.
An additional 1/4 bit synchronization circuit 412 is 21 utilized, connected to the internal bus 44. This is the 22 previously noted timing control which establishes the proper 23 location of each bit within 1/4 bit.
24 In operation, the remote station is addressed by a signal carried on the DS-l stream. This signal is recognized 26 by the microprocessor, which causes the transmission of a 27 predetermined signal on a time slot designated in the 28 instruction following the address to the outgoing bit stream 29 within the designated time slot in succeeding frames~
The central station then sends a predetermined word, 31 such as a HEX10 (00001000) down the DS-l stream as a frame bit 32 pattern. This signal is retransmitted or looped ~ack on the 33 return DS-l stream. After determining the two-way delay, it 34 sends an instruction to microprocessor 410 to change the delay within delay compensation circuit 411 that amount which causes 36 signals transmitted to be advanced from the time slot at the 37 central station the proper amount in the next frame, for 38 example, so that it arrives at the central station exactly 39 within the proper time slot.

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Fine control of each individual bit within the time slot is provided by circuitry 412, which will be describ-ed in more detail later.
Turning now to Figure 5, a more detailed schema--tic of the transmit delay compensation circuit at the remote station is shown. This circuit corresponds to delay compen-sation circuit 411 in Figure 4 with a portion of the 1/4 bit synchronization circuit 412 of the same figure.
Input data is received on data bus 51 and is appl-ied to latch circuit 52, which can be, for a parallel 4 bit data bus, a quad D flip flop chip. The output Q0-Q3 of latch circuit 52 is connected to the data input terminals Dil-Di4 of a RAM ~memory) 53. The output terminals Dol~Do4 of RAM
53 are connected to the data input terminals Do~D3 of latch circuit 54, which also can be a quad D flip flop chip. The data output Qo-Q3 of latch 54 can be connected to a data out-put bus 55, but is preferred to be connected to the data in-put Do~D3 of a further quad D flip Elop chip 56, which is used for 1/4 bit delay compensation (fine control) as will be described in more detail later.
The RAM 53 is addressed as follows. A clock source CLK is connected to the clock input of an 8 bit counter 57, which is caused to continuously cycle. The output terminals of the counter are connected to a pair of 4 bit adders 58 and 59 (or an 8 bit adder if available). I'he outputs of the counter are connected to inputs Al-A~ of adder 58 and inputs ~5~7~
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. A1-A4 of adcler 59.
The sum outputs o adders 58 and 59 ~re connected . to the acldress inputs Ao-A7 oE RAM 53.
~ A pLura1ity oE AND gates 510 have their outputs - connectecl to corresponding inputs B1-B4 of each of adders 58 and 59.
One input of each of the AND gates 510 is connect-ed to the source of clock pulses CLK, and the other inputs are connected to corresponding outputs of a HEX D flip flop chip 511. Inputs Do-~5 of the HEX ~ flip 10p 511 are con-nected to the data bus which is connected to the micropro-cessor shown in Figure 4.

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01 The clock input oE quad flip flop 56 is connected to 02 the output of a solid state switch matrix 512. A pair oE
03 control inputs 513 are connected to the switch matrix 512, and 04 signal inputs 514 are connected thereto whereby one of them can 05 be connected to the clock input of quad flip flop 56.
06 In operation, data signals are carried by data bus 51 07 for transmis~ion to modem 43 (Figure 4) and incorporation in 08 the outgoing DS-l stream. The data is latched in latch circuit 09 52, and appears at the data inputs of RAM 53. The local clock, synchronized to the incoming data pulses by external circuitry, 12 and connected to the WRIT~ ENABLE (WE) input of RAM 53~ causes 13 the RAM to write the incoming data into various address 14 locations.
The clock also operates 8 bit counter 57; which 16 continuously cycles, applying data signals to the A inputs of 17 adders 58 and 59. Assuming that no signals are present at the 18 B inputs, the sum outputs of adders 58 and 59 simply correspond 19 to the input signal from counter 57. This signal is applied to the address lnputs Ao-A7 of the R~M, designating the address to 21 which the incoming data from data bus 51 is to be written~
22 Each time the clock pulse is low, the RAM writes the 23 data latched in latch circuit 52 into the address designated by 24 the data signal stored in adders 5~ and 59. With each ~uccessive clock pulse, counter 57 advances, advancing the 26 address at which the next input data signal is to be stored.
27 Once the last address designated by the counter has been filled 28 in RAM 53, counter 57 recycles the addresses, and the ne~ data 29 is written over the old data at the originally, successively advancing address locations.
31 With the microprocessor having registered a time 32 advance signal sent from the central control via the DS 1 bit 33 stream for ~EX D flip flop 511, the latter flip flop is 34 accessed, and the data signal designated therefor is applied to data inputs Do-Ds of flip flop 511. This signal designates the 36 time advance offset, which is stored (or latched) in flip flop 37 511. The stored signal appears at outputs Qo-Qs of flip flop

3~ 511 and is applied to corresponding inputs of AND gates 510.
39 As noted earlier, during the clock low interval the ~1 13 02 RAM 53 is enabled ~o write data at address locations designated 03 by the count on 8 bit counter 57. Since the clock signal is 04 low, AND gates 510 are not enabled.
05 However during the clock high interval, ~AM 53 is 06 inhibited from writing, and is enabled to read data out. AND
07 gates 510 are also enabled, and transmit to the B inputs of 08 adders 58 and 59 the binary number stored in H~X D flip flop 09 511. Adders 58 and 59 add this number to the number counted on 8 bit counter 57, and the sum outputs designate new addresses 11 in RAM 53. These new addresses desi~nate the memory locations 12 of the bits to be read out from RAM 53, which bits appear at 13 outputs Dol-Do4/ and are stored in latch circuit 54. These 14 bits form the signal ultimately appearing on the data output bus 55 which are applied to modem 43 (Figure 4~ and ultimately 16 appear in the outgoing DS-l stream.
17 As counter 57 advances, input data is written into 18 RAM 53 at successively advancing addresses designated by the 19 binary number provided rom continuously cycling counter 57.
Data is read out from RAM 53 from addresses 21 designated by the sum of the address provided from counter 57 22 and the number stored in quad flip flop 511. The read address 23 thus is in advance of the data written into RAM 53 (or can, 24 alternatively, be considered as one frame delay less the noted advance).
26 Clearly the binary number stored in flip flop 511 27 desi~nates the advance offset, and can be varied as required 28 under control of the microprocessor, under instruction from the 29 central control.
A fine control of synchronization is provided by 31 which the output data bits can be varied in time by 1/4 bit at 32 a time. For this purpose three clock sources which are out of 33 phase by 1/4 bit are applied to corresponding leads of signal 34 inputs 514 of switch matrix 512. Control inputs 513 are connected to clock phase select leads 513 from the 36 microprocessor. With a control signal on one or both of leads 37 513, one or another of the clock phase inputs on lead 514 are 38 switched to the output lead of switch matrix 512, and applied 39 to the clock input of quad flip flop 516. Since the output ~S87~3g 1~
01 signals from the RAM are stored in latch 5~ and are applied to 02 flip flop 56 before beiny applied to 3ata output bus 55, the 03 clock phase applied to flip flop 56 controls the phase of the 04 bits applied to data output bus 55. Accordingly the clock 05 control leads 513 control the phase to 1/4 bit accuracy of the 06 data being applied to the data output bus 55, by synchroni~ing 07 to one of the clock phases applied to leads 514.
08 Leads 514 are respectively connected to clock sources BC2, BCl, and BC2. The mode of automatically determining the 11 measuring the phase oE data transmitted by the remote unit will 12 now be described with reference to Figure 6.
13 Three flip flops 60, 61 and 62 have their data inputs 14 connected together to a source of the input serial data bit stream, i.e., to the received DS-l data stream. Clock source 17 BCl is connected to the clock input of flip flop 60 and samples 18 the received data at its presumed centre. Clock source BC2 is 1~ connected to the clock input of flip flop 61 and the 21 opposite phase of the clock source, BC2, is connected to the 22 clock input of flip flop 62. It may therefore be seen that as 23 clock BC2 advances, the input data appears alternately at 24 output Q of flip flops 61 and 62.
The rising edge of BC2 occurs 1/4 bit before that of 27 BCl. Therefore flip flop 61 samples the data 1/4 bit before 29 the assumed centre. The rising edge of BC2 occurs 1/4 bit 31 after that of BCl. Therefore flip flop 62 samples the data 1/4 32 bit after the assumed centre.
33 The Q outputs are respectively connected to 34 corresponding inputs of EXCLUSIVE OR gates 63 and 64. The other inputs of EXCLUSIVE OR gates 63 and 64 are connected 36 .ogether and to a flip flop 60.
37 The input data applied to flip flops 60~ 61 and 62 38 is taken from the data received from the remote unit. It is 39 only the phase of the pulses which are of concern, and not the actual data.
41 The output of EXCLUSIVE OR gates 63 and 64 are 373~

01 connected respectively to one input of corresponding OR gates 02 65 and 66. The outputs thereof are respectively connected to 03 the data inputs of corresponding flip 10ps 67 and 05 68. The Q outputs of flip flops 67 and 68 are respectively 06 connected to the second inputs of the corresponding inverting 07 OR gates 65 and 66. A clock source is connected to the clock 08 inputs of flip flops 67 and 68r and the Q outputs thereof form 09 the outp~ts of the circuit QCCl and QCC2, representing the difference in the sampled, from the received data.
11 The data to be transmitted is sampled at the assumed 12 centre of the received bit. The output data should preferably 13 not be shifted more than 1/4 bit from the center of the 14 received bit. The sampled output data is therefore checked for conformity with this criterion.
16 Having described the coarse and fine control of 17 timing at the remote station, a description of the central 18 station automatic synchronization control will now be made with 19 reference to Fi~ure 7. This synchronization control is to be used in conjunction with a digital transmission system in which 21 a central station polls remote stations which return data in 22 the DS-l format (preferably) which was described earlier. Such 23 systems as T-l carrier which use the DS-l format are well 24 known, and is assumed that a person skilled in the art using this invention can provide a preferably microproccesor 26 controlled polling system as noted. The central station should 27 have the capability of selecting a particular remote station by 28 address and recognizing a returned signal from that station, 29 and of formating and for~arded messages thereto and for receiving them therefrom.
31 The central control automatically adjusts the 32 synchronization in two stages: ~a) bit phase, and (b) frame 33 phaseO Bit phase adjustment is effected first, and is done in 34 1/4 bit adjustments. Frame phase adjustment is made in 1 bit adjustments.
36 When the power is first turned on, the central 37 control applies a DS-l signal including a frame hit pa-ttern 38 (preferably HEX10) down the transmission medium to all remote 39 stations. It is preferred that the ~entral station should fill 3~

02 the time slot assignments ~ h "fillerl' data which provides bit 03 transitions, but no instructions or data, to the remote 0~ stations.
05 With reception of the signal from the central 06 station, all of the remote stations synchroniæe their local 07 clocks in a well known manner. After a period of time 08 sufficient to allow the remote stations to synchronize to the 09 DS-l clock rate, the central station should forward a signal addressed to the first remote station to be synchroni~ation 11 corrected. The original signal is transmitted back to the 12 central station.
-13 As was noted earlier, it is preferred that there 14 should be two DS-l transmission lines in each direction.
Accordingly the two received DS-l lines 71 and 72 are shown in 16 Figure 7 and the received signals are applied to corresponding 17 three bit shift registers comprising, in one embodiment, flip 18 flops 73a, 74a, and 75a connected in series to the first DS-l 19 line 71, and 73b, 74b and 75b series connected to the second DS-l line 72. The Elip flops are connected to a clock source 21 operating at four times the DS-l rate. If only one incoming 22 line is used, one of the shift registers will of course be 23 deleted.
24 The Q output of each of the flip flops is connected to a data selector 76, whose function will be described in more 26 detail below.
27 The output of the center flip flops 74a and 74b are 28 respectively connected to corresponding flip flops 77a and 77b, 29 which latter flip flops are connected to a source of c~ock pulses operating at the DS-l rate. The Q outputs of flip flops 31 77a and 77b are connected to the output DS-l lines 78 and 79.
32 The remote station address from the received signal 33 is applied via address bus 710 to comparator 711. At the same 34 time the address of the selected station had been loaded into a register 712 from data bus 713 by the local microprocessor.
~6 The register is enabled through well known circuitry from the 37 microprocess including application of a write signal applied 38 through OR gate 714, or the presence of the selected address 39 code on a selected address bus 715 applied to a decoder 716, ~5~37~

02 which provides a write signal through OR gate 714 to register 03 712 when the address has been decoded. The selected address 04 bus is present at the time of reception oE the received signal 05 Erom the designated remote station.
06 The selected address and the received signal source 07 address are compared in comparator 711 and if they match, an 08 output pulse is generated. A circuit 716 detects the output 09 pulse at the output of comparator 711 and provides a control signal on leads 716 to data selector 76 The function of this 11 selection is determine whether the address of the received 12 signal has its source on ~S-l line 71 or DS-l line 72. As a 13 result, the incoming data signals applied to either one of the 14 two 3 bit shift registers comprising flip flop 73a, 74a and 75a or 73b, 74b and 75b is selected.
16 Let us assume for example that the shift register 17 connected to DS-l line 71 has been selected. Data selector 76 18 connects the ~ outputs of flip flops 73a, 74a and 75a through 19 to EXCLUSIVE OR gates 717 and 718. One terminal of EXCLUSIVE
OR gates 717 and 718 are connected toge-ther to the output of 21 flip flop 74a, the other input to EXCLUSIVE OR gate 717 is 22 connected to the output of flip flop 73a, and the other input 23 to EXCLUSIVE OR gate 718 is connected to the output of flip 24 flop 75a by data selector 76.
A comparison of the signals stored in the flip flops 26 of the shift register is thus made, 1/4 bit at a time (due to 27 the clock rate of 4 times the DS-l clock applied to the shift 28 register flip flops~. If the outputs of flip flops 73a and 74a 29 are different, the outgoing DS-l signal is late with respect to the incoming rate. If the outputs of flip flops 74a and 75a 31 are different, the outgoing DS-l signal is early, or in 32 advance, relative to the incoming signal rate. If the outputs 33 of all three flip flops are the same, the incoming bit stream 34 is in phase with the outgoing.
The output of EXCLUSIVE OR gate 718, carrying a 36 signal designating phase delay of the outgoing signal relative 37 to the incoming is connected to a late counter 719, and the 38 output oE EXCLUSIVE OR gate 717 is connected to an early 39 counter 720. Each of counters 719 and 720 are clocked at the ~3 58~

02 DS-l rate. Assuming that the outgoing signal is late relative 03 to the incoming, each time a DS-l frame occurs, late counter 04 719 is clocked, and advances its count. Conversely for phase 05 advance, counter 720 accumulates a digit count for each Erame.
06 The microprocessor addresses counters 719 and 720 via 07 line decoder 716, which apply their digit counts (one of which 08 will be zero if there is no exact synchronization) to data bus 09 713 through tri-state gates 721 (only of which is shown here for each counter). Reading the count from the addressed 11 counter, the microprocessor formulates and transmits a message 12 to the remote station to cause it to advance or delay the phase 13 of its outgoing signal in the manner described earlier, to 14 synchronize its phase with the phase of the outgoiny bits at the c~ntral station.
16 When there is no further phase adjustment re~uired as 17 evidenced by both counters 719 and 720 registering no phase 18 difference counts, the next stage of frame phase adjustment is 19 undertaken. There are two general methods of frame phase adjustment which will be described below~ both with the aid of 21 Figure 7.
22 Using the first technique of frame phase ajustment, 23 the microprocessor causes a pulse to be transmitted in the 24 fourth bit position of the first time slot of a frame looped or retransmitted by the remote station back to the central 26 station. It will be recalled that each frame is comprised of a 27 193 bits, one of which is the frame (synchroniza-tion) bit, and 28 the remaining 192 bits being divided into 24 time slots, each B
29 bits in length. The fourth bit position thus occurs centrally at about 1/2 the time into the time slot. The microprocessor 31 sets either an internal or external counter at the first bit 32 position, and expects to receive the returned bit four counts 33 later.
34 One of the two flip flops 77a and 77b (both clocked at the DS-l rate), selected as the DS-l lines 71 or 72 36 described earlier, has its output applied via data selector 76 37 to a latch, illustrated in Figure 7 and labelled as a counter 38 (for the second technique) 722. In this embodiment however, 39 the block 722 is a latch for storage of the received bit for ~S~'7;3~

02 transer to data bus 713 via tri-state gate 723. The ~ate is 03 enabled by the microprocessor upon decoding of its address in 04 line decoder 716.
05 Alternatively, and pre~erably, block 722 is a serial 06 to parallel shift register operating directly from the output 07 of data selector 76. The bit received ~rom the flip Elop 77 is 08 thus stored therein for reception by the microprocessor upon 09 addressing.
With the microprocessor polling the tri-state gate 11 723 at the fourth bit position, if the expected pulse is 12 present, it recognizes that the frames are exactly in phase, 13 and no further phase adjustment of the remote station is 14 required.
However iE the pulse is not present, the 16 microprocessor prepares and forwards an instruction to the 17 remote station to advance its synchroniza-tion, in a manner }8 described earlier. If the microprocessor detects bits stored 19 in the shift register (722), it can recognize the bit position, and formulate an instruction to the remo-te station to introduce 21 synchronization delay in order to move the bit to the fourth 22 bit position. If the signal bit is in the fourth bit position, 23 of course the entire frame is in synchronization. It should be 24 recognized ~hat a 1 bit in the fourth bit position corresponds to the 1 bit in a ~lEX10.
26 Once the address of remote station has been 27 synchronization adjusted, transmitting at the correct tilne for 28 synchronization at the central office, the central sta-tion 29 addresses a second remote station, repeating the sequence described above. Eventually all of the remote stations are 31 brought into synchronization, their clocks being synchronized 32 to the DS-l rate, with time offsets according -to the last 33 adjustment ordered from the central station.
34 A second technique of frame phase adjustment will now be described. As noted earlier, in the DS-l protocol, the 36 frame bits form a code repeated every twelve frames.
37 Since the bit phase has already been adjusted, the 38 outputs of flip flops 74a and 74b are assumed to be an accurate 39 representation of the input signal, and these are applied to 37~9 02 flip flops 77a and 77b which are clocked at the DS-l rate.
03 Their outputs are applied to data selector 76 which, in a 04 manner described earlier, selects the output of one of flip 05 flops 77a and 77b.
06 The output o~ the latter ~lip flop is applied via -07 data selector 76 to the input of a comparator 724. Also 08 applied to comparator 724 is a signal consisting of the frame 09 bit pattern which has been received by the central station, looped therefrom by the remote station. The output of 11 comparator 72~ is applied to counter 722. The output of 12 counter 722 is applied to the input of tri-state gates 723 13 (only one of which is shown for clarity), the output of which 14 is applied to data bus 713. Gates 723 are enabled upon addressing from the microprocessor, their address being decoded 16 in decoder 716, which is connected to the enable input of gate 17 723.
18 If the frame bit pattern is the same as the received 19 frame bits, the comparator will indicate this and output a signal to the counter of a kind which does not advance it. If 21 the counter, after 12 frames, contains a count, clearly the 22 frames are out of synchronization, and this is read by the 23 microprocessor as described earlier.
24 It is necessary to specify which bit of the received frame is to be compared with the outgoing frame bit pattern, 26 and the result registered in counter 722. This specification 27 is effected by clocking the coun-ter from a frame bit pattern 28 sampling signal lead. A clock pulse is applied to this lead in 29 synchronism with the particular pulse of each frame to be compared. For example, if it is the second pulse of each frame 31 which is to be compared for conformity with the outgoing frame 32 bit pattern, a clock pulse is applied on the frame bit pattern 33 sampling signal lead at the same time as the second bit of the 34 outgoing DS-l stream from the central station to the remote station. The object, of course, is to find the time location 36 of the frame bit. If counter 722 registers a count after each 37 12 frames, the counter microprocessor clears and the frame bit 38 pattern sampling signal is advanced one bit; the next bit in 39 each frame is examined by clocking counter 722 at the third bit 02 in each ~rame.
03 The frame bit pattern sampling signal is derived from 0~ the central control clock source. The DS-l bit stream is n5 normally obtained by originating a DS~l clock rate, and 06 logically obtaining signals corresponding to some or all of ~he 07 bit positions. Accordingly frame bits, 193 bits apart, are 08 normally generated.
09 A position counter, either in the microprocessor or a separte component, registers zero when the frame bit pattern 11 sampling signal is at the frame bit position as generated by 12 the central control. Assuming that counter 722 registers a 13 count, as described above, it is cleared and the frame bit 14 pattern sampling signal is connected to the source of signals corresponding to the first bit position, under control of the 16 microprocessor. At that time the position counter, previously 17 registering zero, is caused to register "1".
18 Again, if no match of the outgoing frame bit pattern 19 with the incoming frame bit pattern is found by counter 722 registering a count, the frame bit pattern sampling signal is 21 connected by the microprocessor to a source of pulses 22 corresponding to the second bit position in each frame. The 23 counter, previously registering "1", is advanced -to "2".
24 In this rnanner each bit position of the incoming signal is compared with the outgoing frame bit pattern for a 26 match. As soon as a match is found, counter 722 registers 27 zero, and the frame phase delay in the loop is known, by the 28 count registered in the bit position counter.
29 The number in this counter is divided by two (to account for the loop being double the length from the remote 31 station to the central station), is subtracted from 193 (the 32 number of the bits in the frame) in the microprocessor, and an 33 instruction is sent by the microprocessor to the remote station 34 to delay the signal by this number oE bits. Frame synchronization thus is obtained.
36 The frame bit pattern sampling signal can also be 37 generated by storing the bit position number the bit in each 38 frame to be sampIed in a first register. The number of the bit 39 being received after the frame bit is also counted and stored ~S~37359 ~2 in a second register. When the bit numbers match, a pulse is 03 generated, and this pulse ~orms the frame blt pattern sampling 04 signal.
05 The timing of the frame bit pattern sampling signal 06 can be shifted by storing an adjacent number in the first 07 register. When the frame bit pattern has been found -to match, 08 the number stored in the first register to generate the frame 09 frame bit pattern sampling signal which corresponds to the frame delay.
11 The operation of the last-described registers can be 12 obtained in the microprocessor which is programmed to effect 13 the operations described in detail above, or alternatively 1~ separate component registers can be usedO
With both the bit phase and frame phase adjusted 16 throughout the entire system, the central office can poll each 17 remote station to enable the for~arding of packets of data in 18 the most efficient manner. The data will be forwarded from 1~ each remote station with one frame delay, but in precise synchronization at the central office.
21 While further phase adjustments may be necessary with 22 temperature variation and aging of components, such variation 23 is minor, and unless a remote station is shut off, the 1/4 bit 24 phase synchronization will be all that is periodically required to be adjusted. Such adjustment can be effected during regular 26 automatic maintenance by the central control, during off-peak 27 hours, or if desired, regularly during idle transmission 28 breaks, which will typically occur se~eral times each second or 29 few seconds.
A complete preferred form of the inven-tion in a 31 system will now be described with reference to Figures 8-11, in 32 which Figure 8 shows the system and Figures 9-11 the 33 synchronization elements thereof.
34 Figure 8 is a block diagram showing elements of a two-way transmission system which uses the preferred embodiment 36 of the self synchronization invention. The synchronization 37 system is depicted using as an example a central station 801, 38 an intermediate station 802 and a subscriber terminal 803.
39 While the aforenoted stations and terminals are used for 7~5~

illustration purposes, it will be realized that the same or similar principles can be used where further intermediate stations are interposed between~ Eor example, the central station and intermediate station 802. For example this sys-tem can be used in a tree-type network, with a single cen-tral station 801, communicating with a plurality of inter-mediate stations along a trunk transmission line, each of these stations communicating with a plurality of interme-diate stations 802 connected along branch transmission lines, each of which communicate with a plurality of subscriber terminals 803. Since this type of system is heirarchial, each lower ordered station synchronizes itself to data signals received from a higher ordered station to which it is connect-ed, and transmits data thereto, in a manner to be described below, so that the data signals are received in proper syn-chronization at the higher ordered station.
The example system shown in Figure 8 is compris-ed of central station 801, as noted earlier, with control terminal 804, which includes a circuit as described with reference to Figure 7 therein. Terminal 804 transmits and receives data via modem 825 and two-way transmission path 826 to intermediate station 802. As noted earlier, ît is preferred that the data should be transmitted according to the ~S-l data format which has been described earlier.
The received data signals which includes control and data bits are demodulated in modem 827, and are passed :$~

into a latch and switching circuit module 828. From the data signals are appl:ied through modem 829, after the con-troL bits are passed to microprocessor 830, which substi-tutes new cont-rol bits and appLies them to the outgoing data path 831 to modem 829. Modem 829 includes a selection switch for applying data from data path 831 to respective outgoing STU drops 832, under control of a connection mem-ory 833 (which retains record of what frames of incoming data are destined for various subscriber terminals), itself under contro:l of microprocessor 830.
A typical subscriber terminal 803 connected to STU drop 832 is shown, with one STU drop connected to a subscriber 02 terminal modem 835. Modem 835 is connected via a bus system 03 836~ whereby data signals are passed to a subscriber terminal 04 microprocessor 837. Various peripheral devices 838 are 05 operated under control of the microprocessor 837 in response to 06 reception o~ data signals over STU drop 832.
07 In order to synchronize the system, each of the 08 intermediate stations and subscriber terminals must be placed 09 into synchronization. As described earlier there is of course delay in the system due to component operation time, 11 transmission path line propagation delays, etc. For example, 12 transmission along a main trunk transmission path may introduce 13 a delay anywhere from close to zero to 1/2 frame; typical 14 propagation delays between intermediate stations or intermediate stations and subscriber terminals each has been 16 typically found to be between close to zero and 1/6th frame.
17 Therefore there is considerable time delay between transmission 18 at the central control and reception at the subscriber 19 terminal. The first step in synchronization is therefore to place each of the units in "receive synchronization".
21 A receive synchronizing circuit 839 is shown in both 22 intermediate station 802 and subscriber terminal 803, and both 23 can be similarly constructed, although a person skilled in the 24 art might introduce variations for specific application. The bit clock output of rnodems 827 and 835 are connected to the 26 input of synchronization circuits 839, and the output of these 27 synchronization circuits are timing signals, on leads 840 and 28 841 respectively. The bit clock is a 1.544 megahertz clock 29 signal, in the preferred embodiment, which is derived from a 12 megahertz carrier signal (via a divide-by-8 circuit in the 31 modem), which carrier signal carries the data bits which are 32 demodulated therefrom in the modem.
33 The receive synchronization circuits are for the 34 purpose of synchronizing the frame timing in each of the stations with the received data frames from the central 36 station. The frame bits transmitted from central station 801 37 preferably forms a HE~10, i.e., a 00001000 pa-ttern; this 38 clearly places the 1 at the approximate center or 4th bit 39 position of a frame. To achieve receive synchronization, the 7~
Gl 26 02 whereupon the counter 846 is allowed to continue counting 193 03 bits, which is a full DS-l frame. Bit synchronization i.s thus 04 achieved.
05 It should be noted that the ~rame bits of the A
06 and~or B channel can be used for obtainin~ synchronization.
07 Since the A channel bits are the least signiEicant bit of each 08 time slot in the 6th frame and every successive 12th frame, if 09 the system is badly out of synchronization, the fifth and seventh frames, for example, will not contain any of the frames 11 bits used for synchronization. Since the synchronization bits 12 may actually appear in those Erames according to the 13 determination of the receiving station or terminal, the bits 14 examined in the assumed 6th frame may not contain ls. In this case the microprocessor shifts examination of bits a full frame 16 time, until it detects a 1, after which it examines each 17 successive frame bit until a HEX10 at the appropriate time is 18 detected.
19 The output of counter 846 is also applied to a divide-by-12 counter, which counts frames. Since in the 21 aforenoted example, the frame bits used for synchronization 22 preferably are in the A channel, the A channel occurring in the 23 6th and each suceeding 12th frame, -the divide-by-12 counter 24 establishes the frame count number, which is determined by timing logic circuit 853. Counter 852 is reset from -the write 26 strobe bus 849 by reset circuit 854. The output of timing 27 logic 853 and counter 846 is a timing bus 855 comprised of 28 leads carrying various timing signals such as frame bit 29 signals, frame 6 timing signals, 8 bit timing signals, etc., as requi~ed for the remaining circuitry.
31 Receive timing is thus achieved in each of the 32 successively lower ordered stations and terminals in the 33 system.
34 While the stations and terminals have now synchronized with the received signals, each is time delayed 36 from the other. However each of the successively higher 37 ordered terminals including the central station must receive 38 signals in proper time frame with its transmitted signal, in 39 order to avoid confusion of received signals from various ~ ~S1~7~

02 whereupon the counter 8~6 is allowed to continue counting 193 03 bits, which is a full DS-l frame. Bit synchronization i.s thus 04 achieved.
05 It should be noted that the ~rame bits of the A
06 and/or B chan~el can be used for obtaining synchronization.
07 Since the A channel bits are the least significant bit of each 08 time slot in the 6th frame and every successive 12th Erame, if 09 the system is badly out of synchronization, the fifth and seventh frames, for example, will not contain any of the frames 11 bits used for synchronization. 5ince the synchronization bits 12 may actually appear in those frames according to the 13 determination of the receiving station or terminal, the bits 14 examined in the assumed 6th ~rame may not contain ls. In this case the microprocessor shifts examination o~ bits a full frame 16 time, until it detects a 1, after which it examines each 17 successive frame bit until a HEX10 at the appropriate time is 18 detected.
19 The output of counter 846 is also applied to a divide-by-12 counter, which counts frames. Since in the 21 aforenoted example, the frame bits used for synchronization 22 preferably are in the A channel, the A channel occurring in the 23 6th and each suceeding 12th frame, the divide-by-12 counter 24 establishes the frame count number, which is determined by timing logic circuit 853. Counter 852 is reset from the write 26 strobe bus 849 by reset circuit 854. The output of timing 27 logic 853 and counter 846 is a timing bus 855 comprised of 28 leads carrying various timing signals such as frame bit 29 signals, frame 6 timing signals, 8 bit timing signals, etc., as required for the remaining circuitry.
31 Receive timing is thus achieved in each of the 32 successively lower ordered stations and terminals in the 33 system.
34 While the stations and terminals have now synchronized with the received signals, each is time delayed 36 from the other. However each of the successively higher 37 ordered terminals including the central station must receive 38 signals in proper time frame with its transmitted signal, in 3g order to avoid confusion of received signals from various ~;87~

02 terminals connected to the bidirectional transmission line.
03 Proper timing is achieved using a delay build out in each of 04 the lower ordered stations and ~ermlnals, which causes their 05 signals to be delayed exactly that amount which is required to 06 place the signal precisely in the proper time slot for 07 reception by the hi~her ordered station. The achievement of 08 this synchronization is here called "transmission 09 synchronization". Two different ways of achieving this are shown in Figures 10 and 11, which are used in the system of 11 Figure 8. An example of the use of the circuit of Figure 10 12 will be described with reference to the subscriber terminal, 13 and an example of use of Figure 11 will be described with 14 reference to the intermediate station of Figure 8.
Assuming that data to be transmitted appears on bus 16 system 836, of Figure 8, this is applied through switching 17 circuit 860 (which can be a tri-state CMOS switch), via a data 18 lead 861 to a delay compensation circuit 862. Here the data is 19 delayed exactly that amount required for it to be received in the same frame (if advanced), or in the next frame if desired, 21 as the data transmitted to the subscriber terminal from the 22 intermediate station 802. In a successful prototype o this 23 invention, data was transmitted from intermediate station 802 24 to subscriber terminal 803 in frame 6, and was applied to delay compensation circuit 862 in frame 5 of the next frame 26 sequence. Of course frame 5 will be delayed from the actual 27 frame 5 at the intermediate station 802, and therefore if 28 transmitted directly back will be delayed and not in 29 synchronization therewith. However delay compensation circuit 862 introduces sufficient delay to cause the data signal 31 applied on lead 861 in frame 5 to be delayed sufficiently that 32 when combined with the return path delay arrives in 33 synchronization with frame 6 at intermediate station 802.
34 It was previously described how the desired delay is determined, i.e., by transmitting a single pulse, a ~EX10, or a 36 predetermined signal in one frame through the system and 37 determining the delay as received at the transmitter. This is 38 used to formulate a delay compensation signal which is 39 transmitted to the microprocessor, such as microprocessor 837.

01 ~8 02 Microprocessor ~37 applies a data word signal to a delay latch 03 863, which applies the signal to delay compensation circuit 04 862, causing it to delay signals on lead 861 by the designated 05 amount. Accordingly the data output from delay compensation 06 circuit 862 to modem 835 for transmission along the subscriber 07 drop 832 back to intermediate station 802 constitutes the 08 proper delay, taking into account the additional line 09 propagation delay from modem 835 to modem 829, as well as the component delay times.
11 Similarly, a 1/4 bit adjustment circuit 863 is 12 controlled by microprocessor 837 via the bus system 836 and 13 applies 1/4 bit clock variation signals to delay compensation 14 circuit 862 as described earlier. The 1/4 adjustment circuit itself is clocked by the transmitting clock is derived from the 16 12 megahertz carrier signals received by modem 335 in a similar 17 manner as the receive clock.
18 In intermediate station 802 the data signals received 19 from modem 829 are applied via lead 864 to delay compensation circuit 865, which has its data output applied to modem 827 for 21 transmission along transmission path 826 to central station 22 801, for adjustment of signals to be received at the central 23 station in proper synchronization. Delay compensation circuit 24 865 is controlled by microprocessor 830, and has a 1/4 bit adjustment circuit 866 also connected thereto for fine 26 correction of data bits.
27 The delay compensation circuit preferred for 28 subscriber terminal 803 is shown in Figure 10. This is 29 comprised of a fixed shift register 870, which has been usefully found to have a delay capacity o~ 128 bits, to which 31 data is input on lead 871. Its output signal is applied to the 32 input of a variable shift register 872, which preferably will 33 introduce a controllable delay of from 0 to 64 bits. It should 3~ be noted that the total possible delay is 192 bits, which is a complete frame with the exception of the frame bit. The outpu-t 36 of shift register 872 is applied to lead 873, which is 37 connected to the modem, i.e. 835 in Figure 8.
38 A delay data word signal is applied from the local 39 microprocessor on data bus 874 to latch 875. Its output sets :
~1 29 02 the specific delay in shift reyister 872. ~ccordingly data 03 signals received on lead 871 are delayed by 128 bits plus the 04 amount of the delay set by the microprocessor in shift register 05 872. Of course the combination of the fi~ed and variable 06 delays can be set according to local experience with whatever 07 line propagation delays are found.
08 The transmit clock signal derived from the incoming 09 carrier, i.e. 12 megahertz is applied to a divide-by-8 counter 876, the output of which is applied to the clock inputs of 11 shift register 870 and 872. This ensures that the output data 12 bits are in phase with the input data bits. However the phase 13 o~ counter 876 can be adjusted in 1/4 bit intervals by applying 14 the output of two bit latch 877 thereto, in order to introduce an additional 1/4 bit when required, the input of latch 877 16 being connected to data bus 874. Since two bits at a time can 17 be introduced to counter 876, its phase can be varied by 2, 4, 18 or 6, where required, in order to adjust the phase by 90, 180, 19 or 270. This fine control ensures correct phase synchronization of data bits at the intermediate station, since 21 the 1/4 bit synchronization is effected under local 22 microprocessor control, with reception of a control signal from 23 intermediate station 802.
24 Another form of delay compensation is shown in Figure 11, which is preferably used in intermediate station 802 to 26 introduce delay to achieve synchronization with a higher 27 ordered station. This form of delay compensation is similar to 28 that described with reference to Figure 5. Typically 29 intermediate station 802 receives signals in one frame, and transmits so that the signals received by the next higher 31 ordered frame are in synchronization with the next frame.
32 Data signals, i.e., received on lead 864 ~Figure 8) - 33 are applied via lead 880 to latch 881. The data is applied to 34 memory 882 at sequential addresses. The addresses are generated by clock pulses from the received bit clock lead 882, 36 there source being derived from the received carrier signal 37 divided down to 1.544 megahertz. The bit clock signals are 38 applied to counter 883, which applies its output count to adder 39 884. The count signals are applied to the address input of 7~

01 memory 882. Since the received data, memory 882 and address 02 are all clocked with the received bit clock, the data signals 03 are stored at sequential addresses established by the 04 increasing count in counter 883 05 To establish the delay, a delay code signal derived 06 from the central control, as described earlier, is applied from 07 the local microprocessor via data bus 885 to a latch ~386. The 08 output of latch 886 is applied to adder 884. Also applied to 09 latch 886 is a chip select signal applied from the microprocessor.
11 When writing data, a signal is not present on the 12 chip select CS lead, and conse~uently there is no output from 13 latch 886, and the address indicated Eor writing is not present 14 in adder 884 from counter 883.
However, during reading, a signal is present on the 16 CS lead, and the address applied to memory 882 is the sum oE
17 the signals applied from counter 883 and latch 886.
18 Accordingly the memory is read at a different address than the 19 one at which it is writing. The address difference, taking into account the clock time, establishes the delay build out.
21 The output of memory 882 is applied to latch 887, to 22 which a bit clock signal is applied in time with the rea~ing 23 cycle. The output of latch 887 is applied to latch 888, and 24 the data output signals are carried on lead 889 to the output modem 827 (Figure 8).
26 ~eans is also provided for 1/4 bit phase adjustment 27 as described earlier. The clock input on latch 888 is 28 connected to a switching circuit 890, which connects the clock 29 output to one of four bit clock phases, each mutually 90 31 out of phase, BCl, BC2/ BCl and BC2. Switching circuit 890 is 32 controlled by leads 891 from the microprocessor. Switching 33 circuit 890 can of course be a logic circuit which controls a 34 plurality of tri-state CMOS switches.
Using the aforenoted circuits, each of the succeeding 36 lower ordered stations places itself in receive synchronization 37 with signals received from higher ordered stations. Each of 38 the stations or terminals also transmits at a time which is 39 specifically delayed so as to cause its ~ata to be received in ~5i~

02 frame synchronization at the next higher ordered station. Due 03 to the delay, the data signals are received in the next higher 04 numbered ~rame. However if desired a station such as the 05 subscriber terminal can transmit at a time which matches the 06 frame number which is transmitted from its associated 07 intermediate station~ In this case it applies data to the ~8 delay build out circuit in the next frame group in a frame 09 number which is previous to the desired received frame number.
The delay build out delays the early transmission to a time 11 exactly matching the transmitted frame. In this manner an 12 entire tree system can self synchronize, allowing the formation 13 of major sized two-way data transmission networks which do not 14 require the intervention of manual synchronization adjustments, and which continuously compensate for variations in 16 transmission and other delays.
17 A person skilled in the art understanding this 18 invention may now conceive of other embodiments or variations 19 thereof. All are considered within the sphere and scope of the invention as defined in the claims appended hereto.

Claims

CLAIMS:
(1) A digital transmission system comprising a central station and a plurality of remote stations, each station including means for transmitting and receiving digital data in a sequence of frames, transmission means arranged between said central station and each of said re-mote stations and causing a variable inherent delay there-between dependent upon the location of the respective re-mote station, the central station including means for trans-mitting a first signal to each of said remote stations chosen in turn and for receiving a signal therefrom depen-dent on the first signal and means for producing from said first signal and said received signal a delay signal repre-sentative of the inherent delay relative to the chosen re-mote station and for transmitting said delay signal to re-mote station, and each remote station including means for receiving and storing said delay signal and means for chang-ing the time of transmission of the transmission means of said remote station in dependence upon said stored delay.
(2) A system as defined in Claim 1 wherein each remote station includes means for synchronizing a nominal time of transmission of said transmission means with data signals received from said central station and wherein said time changing means advances the actual time of transmis-sion relative to said nominal time in dependence upon said stored delay.

(3) A system as defined in Claim 1, wherein the transmission means is of the tree-type arranged to connect from said central station to each of said remote stations effectively sequentially.
(4) A system as defined in Claim 1 wherein the transmitting and receiving means are arranged such that each frame includes a plurality of time slots, wherein each re-mote station includes means responsive to said first signal to transmit signals in a time slot designated by said first signal and wherein said delay signal producing means com-prises means for determining the time difference between said designated time slot at the central control and the signals received from said remote unit in said designated time slot.
(5) A system as defined in Claim 1 wherein the transmitting and receiving means are arranged such that each frame includes a plurality of bits, wherein each remote station includes means responsive to said first signal to transmit a bit at a predetermined time in a frame, and wherein said delay signal producing means comprises means for determining the time difference of the bit in the frame at the central station from the time of the bit in the frame upon reception from the remote station.
(6) A system according to Claim 1 wherein each remote station includes means responsive to said first signal for transmitting first data signals having a repe-titive predetermined pattern of data bits at regular time-spaced intervals and wherein the central station includes means for sensing individual data bits at the pattern rate, means for storing a representatiion of the predetermined pattern and comparing it with the sensed bits, means re-sponsive to the absence of a match between the sensed pat-tern and the stored pattern for shifting the rate of pattern sensing by one bit for each such absence sensed and means responsive to a match between the sensed pattern and the stored pattern for counting the numbers of such shifts.
(7) A system as defined in Claim 4 in which the central control includes a counter, means for causing the counter to begin counting at a predetermined time in said designated time slot, means for stopping the counter upon reception of said signals at a corresponding predetermined time in a received one of said designated time slots, and means for transmitting a signal representative of the count reached by the counter after the counter has stopped count-ing, to the remote unit, to control the change of time of transmission by said remote unit of said designated time slot.
(8) A system as defined in Claim 4, in which the remote unit includes a memory, means for applying data signals to the memory, means for generating a write address signal for addressing the memory whereby the data signals are written into the memory, means for registering said signal representative of said count, means for generating a read address signal offset from the write address by said signal representative of said count, and means for address-ing the memory with the read address signal whereby the data stored in the memory in read out for transmission to the central control.
(9) A system as defined in Claim 7, in which the remote unit is comprised of a digital memory adapted to store data signals input thereto, cycling counter means for genera-ting address signals, adder means having a first plurality of inputs connected to the output of the counter means and having a plurality of outputs connected to the address in-puts of the memory, a plurality of latches adapted to store a data signal corresponding to said count reached by the central control counter, the outputs of the latches being connected via a corresponding plurality of gates to a second plurality of inputs of the adder means, the memory hav-ing a plurality of data output terminals, means for enabl-ing the write control of the memory and the adder means to apply the address signals applied thereto by the counter to to the address terminals of the memory whereby data signals applied thereto are written and are stored therein, and means for enabling said gates whereby the data signal stor-ed in the plurality of latches is applied to the adder means for causing the address signals applied to the memory to be the sum of the data signal applied from the cycling counter and the data signal stored in the plurality of latches, whereby the data signals are progressively stored at first sequential memory locations of the memory and are progressively read out of the memory from second sequential memory locations offset from the first sequential memory locations by the data signal stored in the plurality of latches.
(10) A system as defined in Claim 9, further in-cluding a second plurality of latches connected to the data output terminals of the memory, for storing the output data therefrom, a clock input to the second plurality of latches for clocking the data out from the latches to a data output bus, a plurality of clock sources each having a phase dif-ferent from each other and means for connecting one of the clock sources to the clock input of the second plurality of latches whereby the phase of the data signal stored in the second plurality of latches applied to the data output bus is controlled.
(11) A system as defined in Claim 5, in which said bit is a frame synchronization bit occurring at a bound-ary of said frame.
(12) A system as defined in Claim 5, in which each frame is comprised of a plurality of time slots, each time slot being comprised of a plurality of bits, said bit occurr-ing at a time period of approximately one half of a designat-ed time slot.
(13) A system as defined in Claim 5, 11 or 12 in which said bit occurs in a signal transmitted from the cen-tral station to the remote station and looped back to the central station.
(14) A system as defined in Claim 5, in which said means for determining said time difference at the cen-tral station is comprised of a 3 bit shift register, means for applying the received signal to the shift register, means for clocking the shift register at 4 times the bit rate of said received signal, means for comparing the bit status in the second bit position of the shift register with the binary bit status in the first and third bit posi-tions of the shift register, first and second comparing means for comparing differences between bits in the second and first bit positions and between bits in the second and first bit position respectively of said shift register at said 4 times the bit rate, for designating the late or early phase difference between bits in transmitted and received digital data signals at the central office in 1/4 bit incr-ments, each count unit designating a 1/4 bit increment, whereby said instruction signal can be established to cause the remote station to vary its time of transmission by 1/4 bit increments to synchronize said transmitted and received bits at the central station to within 1/4 bit.
(15) A system as defined in Claim 14, in which each frame is comprised of a plurality of time slots, each time slot being comprised of a plurality of bits, and bit occurring at a designated bit position within a designated time slot.
(16) A system as defined in Claim 5, 14 or 15, in which the transmitted and received bits are substantial ly in phase at the central station, said means for deter-mining said time difference comprising means for transmit-ting a predetermined digital signal to said remote station, means at the remote station for looping said predetermined signal back to the central station, means at the central station for comparing the time of transmission of said pre-determined signal with the time of reception of the prede-termined signal from the remote station, to establish said time difference.
(17) A system as defined in Claim 5, 14 or 15, in which the transmitted and received bits are substantial-ly in phase, in which each frame includes a frame synchron-ization bit arriving at a designated time in each frame, groups of frame synchronization bits forming repetitively cycling frame bit patterns transmitted by the central sta-tion, means at the remote station for looping the frame bit pattern back to the central station, means at the central station for comparing the transmitted frame bit pattern with the received frame bit pattern, a counter clocked with each transmitted frame bit, connected to the comparing means for counting each time a transmitted and received frame bit is different, whereby said instruction signal can be esta-blished to cause said remote station to vary its time of trans-mission of each frame by one bit each time said counter re-gisters a count.
(18) A system as deinfed in Claim 5, 14 or 15, in which the transmitted and received bits are substantial-ly in phase, in which each frame includes a frame synchron-ization bit arriving at a designated time in each frame, groups of frame synchronization bits forming repetitively cycling frame bit patterns transmitted by the central sta-tion, means at the remote station for looping the frame bit pattern back to the central station, means at the cen-tral station for comparing the transmitted frame bit pat tern with the received frame bit pattern, a first counter clocked with each transmitted frame bit, connected to the comparing means for counting each time a transmitted and re-ceived frame bit is different, means for clocking the first counter by a frame bit pattern sampling signal, a second counter for storing a digital designation of the number of a bit from the beginning of a frame to be applied to the first counter in each received frame for comparison with the transmitted frame bit, means for generating a pulse com-prising the frame bit pattern sampling signal each time the number of a received bit from the beginning of each frame matches the number stored in the second counter, means for sequentially increasing the number stored in the second counter each time the first counter registers a count, whereby the number stored in the second counter when the first counter registers no counts over the period of at least one frame bit pattern is designative of the frame time difference.
(19) A system as defined in Claim 5, in which said means for determining said time difference is comprised of means for comparing the phase difference between trans-mitted and received bits at the central station for esta-blishing said instruction signal for transmission to the remote station to cause it to vary its time of transmission to bring said transmitted and received bits at the central station substantially into phase, and further means for com-paring the number of bits of phase difference between trans-mitted and received frames which are in substantial bit phase for establishing a further said instruction signal for trans-mission to the remote station to cause it to vary its time of transmission by said number of bits to cause it to vary its time of transmission to bring said transmitted and re-ceived frames and bits into substantial synchronization at the central station.
(20) A system as defined in Claim 5, 14 or 19, in which each remote station includes a memory, means for applying data signals to the memory, means for generating a write address signal for addressing the memory whereby the data signals are written into the memory, means for re-gistering said signal representative of said count, means for generating a read address signal offset from the write address by said signal representative of said count, and means for addressing the memory with the read adders signal whereby the data stored in the memory is read out for transmission to the central. control.
(21) A system as defined in Claim 14, in which each remote station is comprised of a digital memory adapted to store data signals input thereto, cycling counter means for generating address signals, adder means having a first plurality of inputs connected to the output of the counter means and having a plurality of outputs connected to the address inputs of the memory, a plurality of latches adapt-ed to store a data signal corresponding to said count reach-ed by the central control counter, the outputs of the latches being connected via a corresponding plurality of gates to a second plurality of data output terminals, means for enabling the write control of the memory and the adder means to apply the address signal applied thereto by the counter to the address terminals of the memory whereby data signals applied thereto are written and are stored therein, and means for enabling said gates whereby the data signal stored in the plurality of latches is applied to the adder means for causing the address signals applied to the memory to be the sum of the data signal applied from the cycling counter and the data signal stored in the plurality of latches, whereby the data signals are progressively stored at first sequential memory locations of the memory and are progressively read out of the memory from second sequential memory locations offset from the first sequential memory locations by the data signal stored in the plurality of latches.
(22) A system as defined in Claim 21, further in-cluding a second plurality of latches connected to the data output terminals of the memory, for storing the output data therefrom, a clock input to the second plurality of latches for clocking the data out from the latches to a data output bus, a plurality of clock sources each having a phase differ-ent from each other and means for connecting one of the clock sources to the clock input of the second plurality of latches whereby the phase of the data signal stored in the second plurality of latches applied to the data output bus is controlled.
(23) A system as defined in Claim 22, in which the phase difference of each of the plurality of clock sources is 1/4 bit.
(24) A digital transmission system comprising a central station and a plurality of remote stations, each station including means for transmitting and receiving digital data signal in a sequence of frames, transmission means arranged between said central station and each of said remote stations and causing a variable inherent delay there-between dependent upon the location of the respective remote station, the central station including means for transmit-ting a first signal to a chosen one of said remote stations and for receiving a signal therefrom dependent on the first signal and means for producing from said first signal and said received signal a delay signal representative of the in-herent delay relative to the chosen remote station and for transmitting said delay signal to said remote station, and each remote station including means for receiving and storing said delay signal, means for synchronizing a nominal time of transmission of the transmission means of said remote sta-tion with data signals received from said central station and means for advancing the actual time of transmission of the transmission means relative to said nominal time in de-pendence upon said stored delay.
(25) A digital transmission system comprising a central station and a plurality of remote stations, each station including means for transmitting and receiving digital data in a sequence of frames, tree-type transmis-sion means arranged from said central station to each of said remote stations effectively sequentially and causing a variable inherent delay between the central station and each of the remote stations dependent upon the location of the respective remote station on the transmission means, the central station including means for transmitting a first signal to each of said remote stations chosen in turn and for receiving a signal therefrom dependent on the first signal and means for producing from said first signal and said received signal a delay signal representative of the in-herent delay relative to the chosen remote station and for transmitting said delay signal to said remote station, and each remote station including means for receiving and stor-ing said delay signal, means for synchronizing a nominal time of transmission of the transmission means of said re-mote station with data signals received from said central station and means for advancing the actual time of trans-mission of the transmission means relative to said nominal time in dependence upon said stored delay.